FI111884B - Helix antenna for dual frequency operation - Google Patents

Description

111884

Dual-frequency helix antenna - Helix antenna for dubbelfrequencing

The invention relates generally to antenna structures for radio equipment. In particular, the invention relates to an antenna structure having two different resonant frequencies. This patent application contemplates a cellular telephone as an exemplary radio device.

Cellular radio systems exist in different parts of the world, with significant differences in their operating frequency ranges. Of the digital cellular radio systems, 10 GSM (Global System for Mobile telecommunications) operating frequencies are 890-960 MHz, JDC (Japanese Digital Cellular) 800 and 1500 MHz, PCN (Personal Communication Network) 1710-1880 MHz and PCS .n (Personal Communication System) 1850-1990 MHz. The American AMPS cellular telephone system is operating at 824-894 MHz and the European cordless DECT (Digital European Cordless Telephone) system is operating at 1880-1900 MHz.

Since the resonance frequency of the prior art radio frequency antenna is known to be related to the antenna length through its wavelength, one antenna cannot be used in more than one matte cellular radio system. In some cases, however, it is desirable that the same telephone may also be used in another frequency band. This requires a working antenna solution in addition to: 'other suitable RF parts.

U.S. Pat. No. 4,442,438 discloses a dual-frequency resonant antenna structure consisting of two helices 101, 102 and one whip element 103. As shown in Figure 1, the helices 101 and 102 are mounted in series and their adjacent ends 104 and 105 form the feed point of the composite structure. The whip element 103 is partially within the upper helix 101 and has a feed point 106 at its lower end. The RF-30 signal is applied to said feed point 106 via a coaxial conductor 107 which is connected to the axis of symmetry of the structure and passes through the lower helix 102. The whip element feed point 106 is connected to the lower end 104 of the upper helix and: the lower helix is connected at its upper end 105 to the conductive and ·; ··; grounded sheath. The first resonance frequency of the structure is the resonance frequency of the composite structure formed by the helices 35 101 and 102, in the exemplary embodiment · 827 MHz. The second resonant frequency of the structure is the common resonant frequency of the upper helix 101 and the whip element 103, in the exemplary embodiment 2111884, 850 MHz. The helix 101 and the whip element 103 are thus dimensioned to have substantially the same resonant frequency.

The structure disclosed in the US patent is relatively complex. The most difficult point 5 of the construction in terms of fabrication technique is the feed point arrangement at the center of the antenna where the lower end 106 of the whip element and lower end 104 of the upper helix must be galvanically connected and its lower helix connected to the sheath of the coaxial conductor The difference between the two resonant frequencies achieved by the structure is small, according to the material disclosed in the patent, because the upper helix 101 and whip element 103 must be dimensioned to have substantially the same resonant frequency and thus not applicable to a GSM and PCN operating telephone. Thus, it is an object of the invention to extend the resonance frequency range of a cellular telephone antenna to better cover the entire frequency band in a single cellular radio system.

FI patent application 963275 (LK-Products) discloses a dual-frequency antenna structure according to Fig. 2, in which, between the ends of a helical antenna 201 wound into a cylindrical coil conductor, there is a junction 202 for another antenna element. The cylindrical coils conductor 201 as the first antenna element of the antenna comprises a lower part 204 and an upper part 205 in its longitudinal axis, and the second '·' · antenna part 203 is connected to the cylindrical coil conductor of which '· 25 The electrical lengths of upward antenna elements are different. The first resonance frequency of the combined antenna array is determined by the sum of the electrical lengths of the common area portion of the antenna elements and the top portion of the first antenna element. The second resonant frequency is determined by the sum of the electrical length of the common lower portion and the upper portion of the second antenna element, respectively. In addition, the resonance of the hair is affected by the interconnection between the antenna elements and by the fact that the * ... antenna elements are electrically conductive bodies in close proximity to each other, so. they load each other. The antenna structure shown in Figure 2 is relatively difficult:. accurately scales to desired frequencies because the connection point between the antenna elements ·; ··. ' it requires quite accurate positioning. In addition, the electrical connection at the junction 35 becomes easily unreliable.

FI patent application 970297 (LK-Products) discloses an antenna according to the principle of figure 3, in which the antenna element 301 has a first end and a second end and a tapping point 302 which is located at a certain position between the ends of the antenna element. The tapping point divides the antenna element asymmetrically such that the electrical length from the tapping point to the upper end is significantly greater than the electrical length from the tapping point to the lower end. An antenna feed line 303, which connects the antenna element electrically to the radio device, is connected to the antenna element at the point of taping. A substantial portion of the feed conductor also serves as a radiating portion, since the feed conductor is electrically unshielded, i.e., there is no conductive material sheath around it. The total electrical length of the antenna structure at the first operating frequency is the sum of the electrical lengths of the feed conductor 303 and the portion of the antenna-10 nozzle element 301 extending from the pin point 302 to the first end. Similarly, the total electrical length of the antenna structure at the second operating frequency is the sum of the electrical lengths of the feed line 303 and the portion of the antenna element 301 extending from the puncture point 302 to the other end. The antenna element 301 may be a helix, a straight conductor, or any combination thereof. A disadvantage of this antenna structure sharks-15 is the difficulty of manufacturing it so that the stud 302 becomes sturdy.

It is an object of the present invention to provide an antenna structure suitable for two frequency bands, which is simple to manufacture and which operates reliably. It is also an object of the invention to provide an antenna structure which is easy to dimension .. for two different operating frequencies. It is a further object of the invention that the · ·: ’antenna structure according to the invention is suitable for large-scale serial production.

The objects of the invention are achieved by using as a antenna element a helix which ..! 'the ascent increases from the feed point.

The antenna according to the invention comprises a cylindrical coil conductor having a certain turn A and a certain turn B and other turns between them. The antenna is characterized in that the slope of the round A is different from the slopes of the round B The slopes of the other rounds between the round A and the B are arranged in order of magnitude between the rise of round A and ·, 30 round B.

It is known per se that a conductive body may have a plurality of resonant frequencies, the lowest of which is the so-called. the fundamental frequency and others are harmonic frequencies. The invention is based on the observation that the value of the resonant frequencies of a cylindrical coil conductor, or helix, is affected by changing the design parameters of the helix at different points in the structure. The basic frequency is determined by the electrical length of the helix wire. In the case of a helix, it is generally referred to as the distance at which the ends of a given rotation are spaced along the longitudinal axis of the helix. When the feed point is at the first end of the helix 4111884 and the pitch of the helix is compacted or thinned towards its other end, the interaction between the turns changes the value of the resonant frequencies. When the number of revolutions, the pitch at different points of the helix, and other dimensioning parameters are suitably selected, the resonance frequencies will be set at points along the frequency axis such that the structure can be used in two frequency ranges of the cellular radio system.

The invention will now be described in more detail with reference to exemplary preferred embodiments and the accompanying drawings, in which: Figure 1 shows a known antenna structure, Figure 2 shows another known antenna structure, Figure 3 shows a third known antenna structure, Figure 4 and Figure 6 shows an antenna according to the invention having a protective cover.

1-3, so that the following description of the invention and its preferred embodiments will mainly refer to Figures 4-6.

Fig. 4 is a sectional view of a helix antenna 400 having seven turns. From feed point 401, the slope x1 of the first turn is greater than the slope x2 of the last turn. The slope of the other laps decreases steadily from the first lap to the last lap. The helix antenna is pre-:. The invention is not limited to the upright position, but the invention does not, of course, limit the use or manufacture of the corresponding antenna in any particular position. The feed point 401 and the helix foot 402 may be implemented by bending the helix wire to form the black line shown in the figure. In an alternative embodiment, the helix is connected at its lower end with respect to the position shown in the figure to a connector portion having a cylindrical recess 30 into which the lowest turns of the helix are inserted. For this purpose, at the lower end of the helix may have a support thread (not shown) which is more densely twisted than the other helix and which, when connected to the connector '·', does not function as a radiating part because the electrically conductive connector member is short-circuited: '·. kee support thread rounds. Other methods known per se for forming a feed point:: 401 and for connecting a helix antenna to a radio device may be used.

Figure 5 shows the so-called. measurement of the reflection coefficient, the reflection coefficient, in which the horizontal axis has a frequency from 700 MHz to 2100 MHz and the vertical axis has a value of the reflection coefficient in dB units. The measurement concerns an antenna according to Figure 4. The triangle symbol on the vertical axis indicates 0 dB, one spacing on the vertical axis is 5 dB, and one spacing on the horizontal axis is 140 MHz. The reflection coefficient describes how much of the radio frequency power supplied to the antenna through the feed point is reflected by the reflector. A low reflection value at a specific frequency means that the antenna is well suited for use at that frequency. Figure 5 shows that the antenna has two resonant frequency bands with a reflectance value well below -10 dB. The first resonant frequency band (s11 <-10dB) is about 880 MHz to 960 MHz and the second resonant frequency band (s11 <-10dB) is about 10 1730 MHz to 1800 MHz.

Instead of densification, helix revolutions can also become sparse, so the elevation may increase away from the feed point. The position of the resonance frequency bands of the antenna according to the invention on the frequency axis depends e.g. the thickness of the helix wire, the pitch of the various turns 15, and the diameter of the helix. The following table shows some measurements for some helices H1, H2, H3, H5, H6, H7, H8, H9 and HIO, where the height of the helix from the beginning of the first turn to the end of the last turn is 22 mm and the length of the helix leg (402 in Figure 4). and a helix wire having a thickness of 0.9 mm, and a helix H1 1 having a helix height of 16 mm, a helix wire having a thickness of 20 0.9 mm, a foot height of 6 mm and a diameter of 3 mm, and a helix H12, • ' with a helix height of 16 mm, a helix wire thickness of 0.8 mm, a leg height of 6 mm and a leg diameter of 3 mm. The values of the lower and upper diameters in the table, •, · are the inner diameters and the frequencies f1 and f3 are the resonance frequencies around which the helix is well suited for use in the frequency band.

25 6 111884 __Hl__H2__H3__H5 (denser)

Bottom diameter / mm__7.1x7,1__2x2 ___ 3x3__77_

Outer diameter / mm__7.1x7.1__8,2x82__14x14__7J_

Increase / mm 4 2.5 5 5 + 4 5 + 4 + 3.5 ______ + 2,3 + 2_

Outer volume / mm3__1110__620 __1530__1110 _

Frequency / Imp, real part f / MHz Re / n f / MHz Re / n f / MHz Re / n f / MHz Re / n

Resonance f 1__935.1 43 902.9 54 893.9 56 898.5 55

Resonance f3__2213 12 2011 21 2046 19 1812 23_

Ratio f3 / fl 2.37 0.28 2.23 0.39 2.29 0.34 2.02 0.42 H6 (thickening) I H7 (decreasing) | H8 (decreasing) 1 H9_

Bottom diameter / mm__71__7,1__71__7,1x7,1_

Outer diameter / mm__71__71___71__2x2_

Increase / mm 6.5 + 5 + 3.5 3 + 3.5 + 4 2 + 3 + 4 + 5 2.3 __ + 2.7 + 2 + 1.8 + 4.4 + 4.6 __ + 6 + 7__

Outer volume / mm3__1110____1110__IHO__510 _

Frequency / Imp, real part f / MHz Re / n f / MHz Re / n f / MHz Re / Π f / MHz Re / Ω

Resonance fl__906.0 55 905.9 47 8896 48 911 4 43_

Resonance O__1771 28 2255 12 2379 10 2371 10_ i '* Suhdefl / fl_ 1.95 0.51 2.49 0.26 2.67 0.21 2.60 0.23 0 · __HIO__Hll * H12 ** __

Bottom diameter / mm__7,1x7.1__5.1x5.1__6,2x6,2__

Oversize / mm__5x5__5.1x5.1__5,4x5.4__ • '· Increase / mm 3.1 1.7 3.5 + 3.0 + 2.4 + 2 +: _______ 1.5 + 1.2 + 1, l + l__

Outer volume / mm3_830 450 __550 _

Frequency / Imp, real part f / MHz Re / n f / MH-Re / n f / MHz Re / n ___

Resonance fl__902.9 48 91U 20 901 21___

Resonance f3__2203 10 2081 12 1801 11___

Ratio O / fl_ 2.43 0.21 2.28 0.6 2.0 0.52 * and **: dimensioning differs from other helixes; above.

In the table, the rise of helices H1, H2, H3, H9, H10 and H11 is at all revolutions. that is, they are not in accordance with the invention. In helices H2, H3, H9, H10 and H12, the diameter of the turns changes between the feed point and the other end of the helix: the lower diameter means the diameter closest to the feed point. The bold values of f3 / fl to 7111884 highlight the helices H5, H6 and H12, which are particularly suitable for GSM / PCN dual mode telephone antennas in terms of resonant frequencies.

Fig. 6 is a cross-sectional view of an antenna 600 of the invention having 5 helix wires 601, a connector 602 made of metal or other highly conductive material, and a cover 603. The lower portion of the connector 602 has threads 604 for mechanically and electrically securing the antenna 600 shown in the picture). The lower part of the helix wire has a dense support thread 605 for engaging the helix wire 601 in the cylindrical recess 10 in the joint portion 602. The support thread is not included in the radiating portion of the antenna. The sheath 603 is of a dielectric material, most preferably injection-molded plastic, and may be secured to the joint by gluing or melting. Supporting portions (not shown) of helix wire 601, such as a cylindrical pin protruding from the upper end of the helix, may be formed in the sheath 603.

15

The present invention is not limited to the exemplary embodiments shown, nor to any particular application, but may be used in antenna applications and at different frequencies, preferably radio frequencies such as UHF and VHF. The structure is advantageously available for mobile phone gadgets. The structure may be modified without departing from the scope of the claims defined in the claims below. The incline of the first and last rounds of the helix can be as much as:. '· Exactly the same if there is a certain second turn between them having a slope other than: the rise of the first lap, if then the first and said second turns; i have other laps between which the pitch changes steadily.

• # «• ·

Claims (6)

An antenna (400; 600) for transmitting and receiving radio frequencies on radio frequency, the antenna comprising a cylinder coil conductor (601) having a given winding A and a given winding B and other windings therebetween, characterized by that the slope (xl) of said winding A is of a different size than the slope (x2) of winding B, the slope of each winding between windings A and B is of a different magnitude than the rises of the other wires between A and B, the rises of the other disorders between the disorders A and B fall in the order of magnitude between the rise of winding A and the rise of winding B and the antenna has two resonant frequency bands. An antenna according to claim 1, characterized in that winding A is the first winding of the cylinder coil which forms part of a radiant part of the antenna at its first end and winding B is the last winding of the cylinder coil at its other end, the first winding comprising the feed point of the antenna (401). . Antenna according to claim 2, characterized in that the pitch (x2) of winding B is smaller than the pitch (xl) of winding A, the pitch of the windings of the cylinder coils decreasing away from the feed point (401). Antenna according to claim 1, characterized in that its first resonant frequency band is substantially the same as a given first functional frequency band within: • the cellular radio system and its second resonant frequency band are substantially the same; 'As a given second operating frequency band within the cellular radio system. An antenna according to claim 1, characterized in that it comprises a connection part (602) and in this a cylindrical depression, into which the first end of the cylinder coil (601) is fitted. Antenna according to claim 5, characterized in that the first end of the cylinder coil conductor (601) comprises a support thread (605) for fitting into the cylindrical-shaped recess of the connection part of the connection part. > I> t · • ·